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. These components see applications in the transport, catalysis and bioengineering industries. The research will focus on wet chemical processes and the study of chemical reactions on the component's surface. We will
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simulations and finite element analysis, with high-heat flux electron beam experiments. The research will simulate and replicate steady, cyclic, and transient thermal loads to better understand PFM behaviour
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involve the following technical tasks: To develop a bespoke simulation environment for forming doubly-curved shell structures from recycled, short-fibre composites To propagate uncertainty in material
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at ever-increasing frequencies, there is a growing need for new high-performance electromagnetic simulation technologies to enable rapid design and optimisation in both research and industry. Towards
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materials. You would work as part of a larger team spread across a number of sites including Warwick and KCL London, who will provide different opportunities for you to develop the research. You would be also
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-efficient research that prevents fatigue failures has pushed towards integrated computational materials engineering approaches that improve competitiveness. These approaches rely on physics-based models
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experiment, theory, and numerical simulations in the department of physics at the University of Exeter. The research question is how to effectively shape electromagnetic radiation when the wavelength reaches
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finding faults in simulation, you'll reduce the need for wasteful physical trial-and-error testing, leading to lower energy consumption and material waste. The project also supports the reliability
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, an expert in radiation–matter interaction and materials simulation (h-index 36, i10-index 69), and Dr Francesco Fanicchia, Research Area Lead: Material Systems for Demanding Environments at the Henry Royce
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an integrated zero-emission system and setting a new benchmark for sustainable innovation. This project will upcycle underutilised olive mill waste (OMW) into high-value products, including plant